Morfometria geométrica e histologia: ferramentas complementares na estimativa do sexo de filhotes da tartaruga marinha Caretta caretta (Linnaeus, 1758) (Testudines, Cheloniidae) dos estados da Bahia e do Espírito Santo

Mendes, Sarah da Silva

21 February 2017

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No. of bitstreams: 0 Previous issue date: 2017-02-21 / FAPEMIG - Fundação de Amparo à Pesquisa do Estado de Minas Gerais / Os filhotes e juvenis de quelônios não apresentam anatomicamente características sexuais secundárias visíveis, não sendo possível diferenciar o sexo através da observação da carapaça. Vários autores defendem a análise histológica como a melhor técnica para se realizar a sexagem de filhotes da espécie Caretta caretta. Os objetivos do presente trabalho foram realizar a identificação sexual de filhotes de C. caretta através da morfometria geométrica da carapaça e plastrão e da histomorfologia, além de verificar se há diferença entre as populações dos estados do Espírito Santo e da Bahia com base na morfometria geométrica da carapaça e plastrão. Foram utilizados 204 filhotes natimortos, coletados em diversos ninhos ao longo da praia de Sítio do Conde, Conde, Bahia, e de Regência Augusta, Linhares, Espírito Santo, ambas localizadas no Brasil. Para a análise morfométrica, cada animal teve a carapaça e o plastrão fotografados e os softwares TPSUtil, TPSDig2 e MorphoJ foram utilizados para a realização das análises pertinentes. Posicionados em decúbito dorsal, os espécimes foram ressecados e o plastrão e vísceras foram removidos para permitir a visualização das gônadas e rins, que depois de fotografados foram armazenados em formalina 10% tamponada. Posteriormente foram submetidos à técnica histológica convencional. Verificou-se uma razão sexual favorável às fêmeas. A análise de componentes principais não apontou diferença na carapaça e plastrão de machos e fêmeas das duas localidades. Apenas a análise de função discriminante revelou que há diferença entre a carapaça e plastrão dos espécimes das diferentes localidades. As gônadas estavam localizadas próximas ao hilo renal, com formato filiforme. Nos ovários foi possível observar o córtex constituído por epitélio cúbico simples ou estratificado bem desenvolvido envolvendo a medula desorganizada e rica em matriz intersticial. O córtex dos testículos era composto por um epitélio pavimentoso simples, medula muito bem desenvolvida e com pouca matriz intersticial, observando-se vários túbulos seminíferos. Trabalhos realizados com filhotes de tartaruga cabeçuda e outras espécies de quelônios, utilizando a morfometria geométrica, também demonstraram haver diferenças na carapaça e no plastrão que distinguem o sexo de filhotes recém nascidos. As características histológicas identificadas foram semelhantes às encontradas por outros autores. Outros trabalhos defendem que a análise macroscópica é suficiente para identificar o sexo de filhotes de tartarugas, o que foi demonstrado efetivamente para Dermochelys coriacea e Chelonia mydas, mas não foi efetivo para C. caretta. A morfometria geométrica se mostrou uma ferramenta promissora cuja análise pôde, conforme nosso estudo, corroborar a existência de duas sub-populações que ocorrem no litoral brasileiro. / The hatchlings and juvenile turtles have not anatomically visible secondary sex characteristics, so it is not possible to differentiate sex by viewing the carapace. Several authors advocate histological analysis as the best technique for performing sex of the Caretta caretta’ hatchlings. The aims of this study were to identify sex of hatchling C. caretta by geometric morphometrics of carapace and plastron and histomorphology and analyze if are difference between populations from Espirito Santo and Bahia by geometric morphometric of carapace and plastron. 204 stillborn hatchlings were collected in different nests along the Sítio do Conde’ Beach, Conde, Bahia and Regência Augusta’ Beach, Espirito Santo, both located in Brazil. For morphometric analysis each animal had photographed the shell and plaston and we used the software TPSUtil, TPSDig2, and MorphoJ for morphometrics analysis. The specimens were positioned and removed the plastron and some viscera to allow visualization of the kidneys and gonads, photographed after they were stored in 10% buffered formalin. The histological analysis followed the steps of conventional histological technique. Principal Components Analyzes do not reveals difference in carapace and plastron between females and males. Just discriminant function reveals there are differences between two localities. The sex ratio was female bias in both localities. The gonads were located near the renal hilum, with threadlike format. Ovarian cortex was possible to observe a welldeveloped cuboidal epithelium, associated with a disorganized medulla and interstitialrich matrix. The cortex of the testes was composed of a thin layer of simple squamous epithelium, a very well-developed medulla and low interstitial matrix, observing several seminiferous tubules clearly distinguishable. Work done with hatchling loggerhead turtles and other species also showed significant differences in the carapace that distinguish the sex of young turtles. The histological features were similar to those identified by other authors, some argue that the macroscopic analysis is sufficient to identify the sex of hatchlings, which has been shown to effectively Dermochelys coriacea and Chelonia mydas, but was not effective in C. caretta. Hormonal measurements were also satisfactory to sex in order to young C. mydas, but authors disagree on this method to other species. Geometric morphometrics proved to be a promising tool whose analysis could, according to our study, corroborate the existence of two subpopulations that occur in the Brazilian coast.

CNPQ::CIENCIAS BIOLOGICAS::ECOLOGIA

Dimorfismo sexual

Morfologia

Morfometria geométrica

Tartaruga cabeçuda

Geometric morphometrics

loggerhead turtle

Morphology

Sexual dimorphism

An Assessment Of Sea Turtle Nesting Behavior In Relation To Hurricane- And Restoration-induced Beach Morphodynamics

Long, Tonya Michele

01 January 2010

Coastal habitats are highly dynamic and vulnerable to landscape-level disturbances such as storms and restoration projects. Along the east coast of Florida these areas are particularly valuable as they provide significant nesting habitat for two sea turtle species, the threatened loggerhead (Caretta caretta) and the endangered green turtle (Chelonia mydas). This coast was heavily impacted by three major hurricanes in 2004 and in some areas by large restoration projects in 2005. Recent remote sensing methods allow for broad evaluation of the shoreline and thus the ability to assess sea turtle nesting habitat at a landscape scale. I collected nesting data for southern Brevard County, Florida from 1989 – 2005 and for Canaveral National Seashore, Florida from 1995 – 2005. I used LiDAR (Light Detection and Ranging) and IfSAR (Interferometric Synthetic Aperture Radar) remote sensing to map sea turtle nesting habitat in both areas following the 2004 hurricanes and any subsequent restoration. Canaveral National Seashore underwent no restoration while southern Brevard County received extensive restoration. Topographic variables (e.g., total sand volume, width, and slope) derived from the remote sensing data were compared across three time periods (pre-hurricane, posthurricane, and recovery period) and I compared nesting success data from 2004 to 2005. I built regression models for 2004 and 2005 to determine which topographic features influenced loggerhead and green turtle nesting the most. Green turtle nesting success declined from 2004 to 2005 only in highly restored areas while loggerhead nesting sucess declined throughout. Hurricanes caused a reduction in most of the topographic variables and restoration predominantly impacted aspects of the beach profile (e.g. slope and width). Loggerheads responded to profile characteristics (e.g. upper and lower iii beach slopes) though green turtles showed no consistent response to topography. The results indicate that both loggerheads and green turtles are sensitive to beach restoration, although loggerhead nesting is more influenced by beach morphology and green turtle nesting may be influenced more by other dune features such as vegetation cover.

Beach erosion

Beaches -- Florida

Green turtle -- Nests -- Florida

Loggerhead turtle -- Nests -- Florida

Sea turtles -- Nests -- Florida

Biology

Natural Resources and Conservation

Nest site fidelity and nest site selection of loggerhead, Caretta Caretta, and leatherback, dermochelys coriacea, turtles in KwaZulu-Natal, South Africa

Botha, Marié

January 2010

Loggerhead and leatherback sea turtles nest on the beaches of the north-eastern portion of Kwazulu-Natal within the iSimangaliso Wetland Park. Loggerheads place ~60 percent of all nests within an 8 km stretch of beach, whereas leatherbacks tend to space their nests more evenly along the entire length of the monitoring area. The study aimed to determine nest site fidelity of loggerheads and leatherbacks (using four decades of nesting data housed by Ezemvelo KZN Wildlife) and the factors that influence nest site selection of both species within the 56 km of turtle monitoring area (32N to 100S) and the 5 km area of high-density loggerhead nesting (0N to 12N). The effectiveness of nest site selection was then determined through the hatching success of loggerheads over the 5km area (0N to 12N). Results showed that loggerheads show a high degree of nest site fidelity (~3 km) with nest site fidelity of individuals increasing over subsequent seasons of nesting, as well as these individuals using the same stretches of beach for nesting (the most popular area being 1N to 4N for repeat nesters). Leatherbacks displayed nest site fidelity of ~9 km and this did not increase over successive seasons of nesting. In terms of nest site selection, loggerheads and leatherbacks both avoided areas where low shore rock was present, whereas both species preferred nesting on beaches of intermediate morphodynamic state. Leatherback nesting was significantly higher in areas with wider surf zones. Both species were able to surpass the high water mark when nesting as nests below this point would be almost certainly doomed. Hatching success of loggerheads was comparative to high (83 %) relative to other studies, however, nest success varied across the beach from beacon 1N to 12N. Areas where highest nest success was observed were not areas of highest nest density presumably due to artificial lighting. Results from this study increase our understanding of the evolutionary biology of loggerhead and leatherback turtles in South Africa and the effectiveness of loggerhead nest site selection through hatching success.

Nest building

Turtles -- Habitat

STAMM, un modèle individu-centré de la dispersion active des tortues marines juvéniles : applications aux cas des tortues luths du Pacifique Ouest et de l'Atlantique Nord-Ouest et aux tortues caouannes de l'ouest de l'océan Indien / STAMM, an individual based model for simulating the active dispersal of juvenile sea turtles : case studies on the western Pacific and the north-western Atlantic leatherback turtle populations and on the loggerhead turtle populations of the western Indian ocean

Lalire, Maxime

26 June 2017

Les tortues marines, espèces emblématiques des écosystèmes marins, sont de plus en plus menacées par les effets directs et indirects des activités humaines. Leur cycle de vie est complexe, partagé entre divers habitats, souvent très éloignés les uns des autres. Leur conservation nécessite donc d'identifier les habitats occupés à chaque stade de vie et les routes migratoires empruntées entre ces différents habitats. Si l'écologie spatiale des tortues adultes est relativement bien connue, notamment grâce au suivi par satellite, il n'en va pas de même pour les juvéniles qui se développent plusieurs années en milieu pélagique sans pouvoir être suivis. Dans ce contexte, les simulations numériques constituent un outil adapté pour explorer la dispersion des tortues juvéniles à partir de leurs plages de naissance. Jusqu'à présent il a le plus souvent été supposé dans ces simulations que les juvéniles dérivaient passivement avec les courants marins. Dans ce travail de thèse nous présentons STAMM (Sea Turtle Active Movement Model), un nouveau modèle de dispersion active des tortues juvéniles qui s'attache à dépasser l'hypothèse initiale d'une dérive purement passive. Dans STAMM, les juvéniles simulés se déplacent sous l'influence de la circulation océanique et d'une nage motivée par la recherche d'habitats favorables. Ce modèle est appliqué ici à l'étude de la dispersion des juvéniles de trois populations de tortues marines : les tortues luths (Dermochelys coriacea) du Pacifique Ouest et de l'Atlantique Nord-Ouest puis les tortues caouannes (Caretta caretta) de l'ouest de l'océan Indien. Nos résultats montrent que, même si la circulation océanique détermine, à grande échelle, les zones de dispersion, la prise en compte des mouvements motivés par l'habitat augmente considérablement le réalisme des simulations et impacte profondément la distribution spatiale et temporelle des individus simulés à l'intérieur de leur zone de dispersion. Les mouvements motivés par l'habitat induisent notamment des migrations saisonnières en latitude qui réduisent la mortalité par hypothermie. Ces mouvements induisent également une concentration des individus simulés dans des zones productives (comme les upwellings de bord Est) inaccessibles en dérive passive. Ces résultats questionnent la vision classique des juvéniles circulant passivement autour des gyres océaniques et devraient rapidement être pris en compte pour la mise en place de mesures de conservation ciblées visant les tortues marines juvéniles. / Sea turtles are increasingly threatened by the direct and indirect effects of human activities. Their life cycle is complex, shared between various, and often very distant, habitats. Their conservation therefore requires identifying the habitats occupied at each stage of life and the migration routes between these different habitats. While the spatial ecology of adult turtles is relatively well known, particularly through satellite monitoring, the situation is not the same for juveniles which pelagic development phase remains largely unobserved. In that context, numerical simulation constitutes an appropriate tool to explore the dispersal of juvenile sea turtles from their natal beaches. Until now, simulations were mostly performed under the assumption that juveniles disperse passively with oceanic currents. In this PhD thesis we present STAMM (Sea Turtle Active Movement Model), a new model of active dispersal that aims to go beyond the initial hypothesis of passive drift. In STAMM, juvenile sea turtles move under the influence of ocean currents and swimming movements motivated by the search for favorable habitats. This model is applied here to the study of the dispersal of juveniles from three sea turtle populations: leatherback turtles (Dermochelys coriacea) of the Western Pacific and the Northwest Atlantic Oceans, and loggerhead turtles (Caretta caretta) of the Western Indian Ocean. Our results show that, although ocean currents broadly shape juvenile dispersal areas, simulations including habitat-driven movements provide more realistic results than passive drift simulations. Habitat-driven movements prove to deeply structure the spatial and temporal distribution of juveniles. In particular, they induce seasonal latitudinal migrations that reduce cold induce mortality. They also push simulated individuals to concentrate in productive areas that cannot be accessed through pure passive drift. These results challenge the classical view of juveniles circulating passively around oceanic gyres. They should rapidly be taken into account for the implementation of targeted conservation measures concerning juvenile sea turtles.

Courants marins

Dispersion

Ecologie spatiale

Modélisation lagrangienne

Modèles de mouvement

Modèles d'habitat

Simulations numériques

Tortues marines juvéniles

Tortue luth

Tortue caouanne

Oceanic currents

Dispersal

Spatial ecology

Lagrangian modelling

Movement modelling

Habitat modelling

Numerical simulations

Jevenile sea turtles

Leatherback turtle

Loggerhead turtle

Predicting leatherback sea turtle sex ratios using spatial interpolation of nesting beach temperatures

Unknown Date

Sex determination in leatherback sea turtles is directed primarily by the temperatures a clutch experiences during the middle third of development. Warmer temperatures tend to produce females will cooler temperatures yield males. Nest temperatures can vary spatially and temporally. During the 2010 and 2011 nesting seasons, this study estimated the hatchling sex ratio of leatherback sea turtles on Sandy Point National Wildlife Refuge (SPNWR), St. Croix, U.S. Virgin Islands. I measured sand temperatures from May- August and across the spatial range of leatherback nesting habitat. I spatially interpolated those temperatures to create maps that predicted temperatures for all nests incubating on SPWNR. Nest temperatures were also directly measured and compared with predicted nest temperatures to validate the prediction model. Sexes of dead-in-nest hatchlings and full term embryos were used to confirm the sex-temperature response. The model showed that microclimatic variation likely impacts the production of both sexes on SPNWR. / Includes bibliography. / Thesis (M.S.)--Florida Atlantic University, 2013.

Sex determination, Genetic

Sex ratios

Vegetation dynamics

DEPREDATION OF OLIVE RIDLEY AND LOGGERHEAD TURTLE CLUTCHES ON BEACHES WITH AND WITHOUT PREDATOR MANAGEMNT

Carlynn Nicole Cornhill (11002167)

23 July 2021

<p>Management of predation on sea turtle nesting beaches is vital to conservation efforts for the vulnerable loggerhead turtles (<i>Caretta caretta</i>) and olive ridley turtles (<i>Lepidochelys olivacea</i>). Sea turtles increasingly face threats from invasive and human-tolerant mammalian predators as human disturbances on nesting beaches rises. The intensity of mammalian predation has increased in Las Baulas National Park in Costa Rica which is an important nesting site for several species of threatened and endangered sea turtles. I analyzed loggerhead and olive ridley nest predation on four beaches in the United States and Costa Rica that were chosen for variations in degree of human disturbance and management strategies. My objectives were to 1) determine if egg predation rates differ at the four sites, 2) determine the most destructive predators at each location, and 3) suggest management options to alleviate mammalian threats to turtle clutches on Playa Grande and Playa Cabuyal in Costa Rica. My results show that the beaches without a nest protection or predator control program had very high rates of predation. Invasive mammalian predators and mammalian predators associated with human disturbance were the most destructive at the four sites. I recommend that regulations regarding dogs and the take of eggs from the beach are enforced at Playa Cabuyal and that physical nest protection is rapidly implemented at Playa Grande. I also recommend that the National Park consider managing raccoon predation by removing problem individuals, but caution that they do so in a way that maintains the animals’ role in the ecosystem.</p>

Marine Biology

Zoology

Behavioural Ecology

Population Ecology

Animal Behaviour

Vertebrate Biology

Global Change Biology

loggerhead turtle, Caretta caretta

Predation risk

human disturbance

sea turtle clutches

Playa Grande

Costa Rica

Playa Cabuyal

Vero Beach

Wassaw Island

Sea Turtle

endangered turtle

Raccoon, Procyon lotor

dog predation